KR102262952B1 - Touch control panel and manufacturing method thereof, touch control display screen - Google Patents

Abstract

The present invention provides a touch control panel including a substrate on which a touch control area and a wiring area located at the edge of the touch control area are installed, the substrate having a metal bridge located in the touch control area and a plurality of first wirings located in the wiring area installed, and an insulating layer covering the metal bridge and the first wiring is further formed on the substrate, and a plurality of first through holes are installed at a position of the touch control region of the insulating layer, and a position corresponding to each of the first wirings are provided with second through-holes, a metal layer is formed on the insulating layer, and the metal layer includes a plurality of induction electrodes located in the touch control region, a plurality of driving electrodes, and a second wiring positioned in the wiring region and connected to the induction electrode and a third wire connected to the driving electrode, wherein the second wire and the third wire correspond one-to-one with the position of the first wire, and both the second wire and the third wire correspond thereto through the second through hole. It is connected to the first wiring, and the plurality of induction electrodes are electrically connected to the metal bridge through the plurality of first through holes. The present invention further provides a manufacturing method and a touch control display screen.

Description

Touch control panel and manufacturing method thereof, touch control display screen

The present invention claims priority to an earlier application filed on February 23, 2017 and the title of the invention is "Touch Control Panel and Manufacturing Method thereof, Touch Control Display Screen", application number 2017101013074. ) is incorporated into this document.

[Technology]

The present invention relates to the field of touch screen technology, and more particularly, to a touch control panel, a manufacturing method thereof, and a touch control display screen.

The in-plane electrode in the visible region of the conventional touch screen is made of a transparent conductive material, and the wiring region around the four is made of metal, and the in-plane and peripheral conductive materials are different materials, so In a single-layer conductive layer touch screen based on the existing Metal Mesh method, since the in-plane and peripheral wiring are all the same metal layer, the metal layer touch control/drive electrode and metal bridge must be manufactured twice normally. If there is only one metal conductive layer in the peripheral wiring, the impedance of the peripheral wiring is relatively high.

The present invention provides a touch control panel and a manufacturing method for effectively reducing the risk of the peripheral wiring being cut by reducing the impedance of the peripheral wiring.

The present application also provides a touch control display screen.

A touch control panel according to the present application includes a substrate provided with a touch control area and a wiring area located at an edge of the touch control area, the substrate having a metal bridge located in the touch control area and a plurality of first wirings located in the wiring area installed, and an insulating layer covering the metal bridge and wiring is further formed on the substrate, a plurality of first through holes are installed at a position of a touch control region of the insulating layer, and a position corresponding to each of the first wirings is further formed All second through-holes are provided, and a metal layer is formed on the insulating layer, and the metal layer includes a plurality of induction electrodes located in a touch control area, a plurality of driving electrodes, and a second second through hole located in a wiring area and connected to the induction electrodes a wiring and a third wiring connected to the driving electrode, wherein the second wiring and the third wiring correspond one-to-one with the position of the first wiring, and the second wiring and the third wiring are both of the second through hole is connected to the first wiring corresponding thereto, and the plurality of induction electrodes are electrically connected to the metal bridge through the plurality of first through holes.

Here, in the insulating layer, a plurality of the second through-holes are provided to be spaced apart from each other in a direction in which each of the first wirings extends.

Here, each of the first through-holes is located between two adjacent induction electrodes spaced apart by the corresponding driving electrode.

Here, the plurality of induction electrodes are arranged in a matrix form, the plurality of driving electrodes are arranged in a matrix form, and the plurality of induction electrodes and the plurality of driving electrodes are alternately insulated and distributed.

In the method of manufacturing a touch control panel according to the present application, the method comprises:

forming a metal bridge in the touch control area of the substrate and at the same time forming a plurality of first wirings in the wiring area of the substrate;

forming an insulating layer covering the metal bridge and the first wiring;

forming a plurality of first through-holes at positions corresponding to the touch control area of the insulating layer and forming second through-holes at positions corresponding to each of the first wirings;

A plurality of induction electrodes, a plurality of driving electrodes, and second and third wires corresponding to positions of the first wires are formed in the insulating layer, and the induction electrodes are connected to the metal through the corresponding first through holes. and connecting the second wire and the third wire to the first wire corresponding thereto through a second through hole.

Here, in the insulating layer, a plurality of the second through-holes are provided to be spaced apart from each other in a direction in which each of the first wirings extends.

Here, each of the first through holes is formed between two adjacent induction electrodes spaced apart by the corresponding driving electrode.

Here, the step of forming the metal bridge in the touch control region of the substrate and the first wiring in the wiring region of the substrate at the same time comprises forming a first metal line layer on the substrate and patterning the first metal layer to form the metal bridge and and forming the first wiring.

Here, the forming of a plurality of induction electrodes, a plurality of driving electrodes, and second and third wirings corresponding to positions of the first wiring in the insulating layer includes forming a second metal layer in the insulating layer, The induction electrode, the driving electrode, the second wiring, and the third wiring are formed by patterning the second metal layer, but in the forming process, a portion of the second metal layer forming the induction electrode is filled in the first through hole to form a metal bridge and a metal bridge. and the second metal layer portion forming the second wiring and the third wiring is connected to the first wiring by filling the second through hole.

The touch control display screen according to the present application includes a display screen module, and further includes the above-described touch control panel, wherein the touch control panel is laminated on the display screen module.

In the touch control panel according to the present application, in the wiring layer of the wiring area, two layers of metal wiring blocked by an insulating layer are installed and connected through a through hole, which is advantageous for reducing the impedance of wiring in the surrounding wiring area and At the same time, the wiring located under the insulating layer effectively reduces the risk of problems such as breakage of the wiring of the corresponding layer due to the protection of the insulating layer, and further improves product reliability.

In order to more clearly describe the structural features and effects of the present invention, the following will be described in detail in conjunction with the drawings and specific examples.
1 is a schematic cross-sectional view of a touch control panel of the present invention.
FIG. 2 is a plan view of the touch control panel shown in FIG. 1 .
3 is a flowchart of a method for manufacturing a touch control panel according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following clearly and completely describes technical solutions in the embodiments of the present invention in conjunction with the accompanying drawings in the embodiments of the present invention. Here, the accompanying drawings are for illustrative purposes only, are merely schematic diagrams, and should not be construed as limitations on the present patent.

1 and 2, the present invention provides a touch control panel and is used for touch control of equipment having a touch control display screen. The touch control panel includes a touch control area 11 and a substrate 10 on which a wiring area 12 positioned at an edge of the touch control area 11 is installed. A metal bridge 13 located in the touch control area 11 and a plurality of first wirings 14 located in the wiring area 12 are installed on the substrate 10 , and the metal bridge is provided on the substrate 10 . An insulating layer 15 covering the 13 and the first wiring 14 is further formed, and a plurality of first through holes 151 are formed in the insulating layer 15 at a position located in the touch control area 11 . are installed, and second through-holes 152 are provided in all positions corresponding to the respective first wirings 14 . A metal layer (not shown) is formed on the insulating layer 15 , and the metal layer is positioned at a plurality of induction electrodes 17 , a plurality of driving electrodes 18 , and a wiring region 12 positioned in the touch control region 11 . and a second wire 19 connected to the induction electrode 17 and a third wire 20 connected to the driving electrode 18, wherein the second wire 19 and the third wire 20 are One-to-one correspondence with the position of the first wire 14 , and the second wire 19 and the third wire 20 are connected to the corresponding first wire 14 through the second through hole 152 . and the plurality of induction electrodes 17 are electrically connected to the metal bridge 13 through the plurality of first through holes 151 .

In this embodiment, the plurality of induction electrodes 17 may be arranged in a matrix form and provided in a plurality of rows along the X-axis direction. The plurality of driving electrodes 18 may be arranged in a matrix and provided in a plurality of rows along the Y-axis direction, and the plurality of induction electrodes 17 and the plurality of driving electrodes 18 may be insulated and distributed alternately. do. In the X-axis direction, the induction electrodes 17 of each row are connected through the first through-holes 151 , and one second wiring 19 is connected to the induction electrodes of each row. The third wiring 20 is connected to the driving electrodes 18 in each row along the Y-axis direction. In other words, the number of the plurality of first wirings is equal to the sum of the total number of the second wirings and the third wirings, and the number of rows of the induction electrode is equal to the number of the second wirings.

Each of the first through holes 151 is located between two adjacent induction electrodes 17 spaced apart by the corresponding driving electrode 18 , that is, the first in the insulating layer 15 . The first through hole 151 is installed at a position where the through hole 151 is spaced apart by the driving electrode 18 between the two induction electrodes 17 along the X-axis direction, and the induction electrode 17 is driven. It can be understood that it is positioned to cross the electrode. The induction electrode 17 is connected to the metal bridge 13 through the first through hole 151 to realize electrical connection between the plurality of induction electrodes 17 in the same row along the X-axis direction.

The connection position of the induction electrode 17 and the first through hole 151 may be planar, that is, the outer surface of the induction electrode 17 is completely flat. Alternatively, the connection position between the induction electrode 17 and the first through hole 151 is a concave portion formed toward the through hole direction, and only needs to be capable of connecting the induction electrode 17 and the metal bridge 13 .

In the present embodiment, a plurality of the second through holes 152 are provided in the insulating layer 15 to be spaced apart from each other in the extending direction of each of the first wirings 14 . In other words, a plurality of spaced apart second through holes 152 may be installed in each of the first wirings 14 , and each second wiring 19 may be provided with a corresponding second through hole 152 through the second through hole 152 . 1 is connected to the wiring 14 . Each of the third wirings 20 is connected to the corresponding first wiring 14 through the second through hole 152 .

In other words, the second wiring 19 is stacked up and down with the first wire 14 corresponding thereto, and the third wire 20 is stacked up and down with the corresponding first wire 14 . installed, the middle is isolated and protected by an insulating layer and electrically connected to each other through a through hole, so that even if the wiring in the wiring area has a double-layer structure, the second wiring 19 and the third wiring 20 in the wiring area The impedance is reduced, and at the same time, the first wiring 14 located under the insulating layer 15 effectively reduces the risk of problems such as breakage of the wiring of the corresponding layer due to the protection of the insulating layer 15, furthermore, the product improve reliability. Here, the first wiring is used to electrically connect each electrode to the main control board.

1, 2 and 3 together, the present invention also provides a method of manufacturing a touch control panel, the method comprising the following steps.

In step S1 , a plurality of first wirings 14 are formed in the wiring region 12 of the substrate 10 while forming the metal bridge 13 in the touch control region 11 of the substrate 10 . It mainly includes forming a first metal wire layer on the substrate 10 and patterning the first metal layer to form the metal bridge 13 and the first wiring 14 .

In step S2, the insulating layer 15 covering the metal bridge 13 and the first wiring 14 is formed. Here, the entire surface of the insulating layer covers the touch control area 11 and the wiring area 12 of the substrate. When the insulating layer 15 covers the first wiring 14 , it protects against this, thereby reducing the risk of problems such as breakage of the first wiring.

In step S3 , a plurality of first through holes 151 are formed in the insulating layer 15 at positions corresponding to the touch control region 11 , and at positions corresponding to the first wirings 14 , respectively. The second through-holes 152 are formed, wherein the number of the second through-holes 20 of each of the first wirings 14 is not limited, and it is preferable to install a plurality of them to be spaced apart, thereby stability of the connection. can be obtained

In step S4 , the plurality of induction electrodes 17 , the plurality of driving electrodes 18 , the second wiring 19 and the third wiring 20 corresponding to the positions of the first wiring 14 are formed in the insulating layer 15 . to form In addition, the induction electrode is connected to the metal bridge through the corresponding first through hole 151 , and the second wiring 19 and the third wiring 20 correspond thereto through the second through hole 152 . to be connected to the first wiring 14 that becomes In this step, a second metal layer is formed on the insulating layer 15, and the second metal layer forms the induction electrode, the driving electrode, the second wiring and the third wiring through a patterning method such as a photomask. , in the process of forming the second metal layer portion forming the induction electrode 17 is filled in the first through hole 151 is connected to the metal bridge 13, the second wiring forming the second wiring and the third wiring and filling the second through hole 152 with the metal layer portion to be connected to the first wiring 14 .

In the present method for manufacturing a touch control panel, a double-layered wiring is formed on the premise that the manufacturing steps are not increased, so that the impedance of the wiring is reduced and the use stability of the wiring is improved.

The present invention further provides a touch control display screen, the touch control display screen comprising a display screen module and the touch control panel, wherein the touch control panel is laminated on the display screen module.

The above is a preferred embodiment of the present invention, and it should be noted that a person skilled in the art can make various improvements and color changes without departing from the principles of the present invention. Color color also falls within the protection scope of the present invention.

Claims (13)

A touch control panel comprising:
a substrate including a touch control area and a wiring area located at an edge of the touch control area, wherein the substrate is provided with a metal bridge located in the touch control area and a plurality of first wirings located in the wiring area, and the substrate is provided with the metal An insulating layer covering the bridge and the first wiring is further formed, a plurality of first through holes are provided at a position of the touch control area of the insulating layer, and each of the first wirings is provided at a position corresponding to each of the first wirings A plurality of second through holes are installed to be spaced apart along the extending direction, a metal layer is formed on the insulating layer, and the metal layer includes a plurality of induction electrodes located in a touch control area, a plurality of driving electrodes, and a location of a wiring area. and a second wiring located in and connected to the induction electrode, and a third wiring connected to the driving electrode, wherein the second wiring and the third wiring correspond one-to-one to the position of the first wiring and form a double-layered wiring, In addition, the second wiring and the third wiring are both connected to the corresponding first wiring through the second through hole, and the plurality of induction electrodes are electrically connected to the metal bridge through the plurality of first through holes. connected,
touch control panel. delete According to claim 1,
Each of the first through-holes is located between two adjacent induction electrodes spaced apart by the corresponding driving electrode,
touch control panel. 4. The method of claim 3,
The plurality of induction electrodes are arranged in a matrix form, the plurality of driving electrodes are arranged in a matrix form, and the plurality of induction electrodes and the plurality of driving electrodes are alternately insulated and distributed.
touch control panel. A method for manufacturing a touch control panel, comprising:
forming a metal bridge in the touch control area of the substrate and at the same time forming a plurality of first wirings in the wiring area of the substrate;
forming an insulating layer covering the metal bridge and the first wiring;
A plurality of first through holes are formed in a position corresponding to the touch control area of the insulating layer, and a plurality of second through holes are formed in a position corresponding to each of the first wirings in a direction in which each of the first wirings extends. through-holes are installed to be spaced apart; and
A plurality of induction electrodes, a plurality of driving electrodes, and second and third wires corresponding to positions of the first wires are formed in the insulating layer, and the induction electrodes are connected to the metal through the corresponding first through holes. to be connected to the bridge, the second wiring and the third wiring are connected to the corresponding first wiring through a second through hole, and the second wiring and the third wiring are the first wiring and the double-layer wiring comprising the step of forming
A method of manufacturing a touch control panel. delete 6. The method of claim 5,
Each of the first through-holes is formed between two adjacent induction electrodes spaced apart by the corresponding driving electrode,
A method of manufacturing a touch control panel. 6. The method of claim 5,
The step of forming the metal bridge in the touch control area of the substrate and the first wiring in the wiring area of the substrate at the same time may include forming a first metal line layer on the substrate and patterning the first metal layer to form the metal bridge and the first wiring. 1 comprising the step of forming a wiring,
A method of manufacturing a touch control panel. 6. The method of claim 5,
The forming of a plurality of induction electrodes, a plurality of driving electrodes, and second and third wirings corresponding to positions of the first wirings in the insulating layer may include forming a second metal layer in the insulating layer, and The induction electrode, the driving electrode, the second wiring and the third wiring are formed by patterning the metal layer, but in the forming process, the portion of the second metal layer forming the induction electrode is filled in the first through hole and connected to the metal bridge, A second metal layer portion forming the second wiring and the third wiring is filled in the second through hole and connected to the first wiring.
A method of manufacturing a touch control panel. A touch control display screen comprising:
including a display screen module,
a touch control panel laminated on the display screen module, wherein the touch control panel includes a touch control area and a substrate on which a wiring area located at an edge of the touch control area is installed, and a metal bridge located on the touch control area on the substrate and a plurality of first wirings positioned in the wiring area are installed, an insulating layer covering the metal bridge and the first wiring is further formed on the substrate, and a plurality of first through holes are formed in the touch control area of the insulating layer. installed, and a plurality of second through-holes are installed to be spaced apart from each other in a direction in which each of the first wires is extended at a position corresponding to each first wire, a metal layer is formed on the insulating layer, and the metal layer includes a plurality of induction electrodes positioned in the touch control region, a plurality of driving electrodes, a second wire positioned in a wiring region position and connected to the induction electrode, and a third wire connected to the driving electrode, wherein the second wire and the second wire The three wirings correspond one-to-one with the position of the first wiring and form a double-layered wiring, and both the second wiring and the third wiring are connected to the corresponding first wiring through the second through hole, A plurality of induction electrodes are electrically connected to the metal bridge through the plurality of first through holes,
Touch control display screen. delete 11. The method of claim 10,
Each of the first through-holes is located between two adjacent induction electrodes spaced apart by the corresponding driving electrode,
Touch control display screen. 13. The method of claim 12,
The plurality of induction electrodes are arranged in a matrix form, the plurality of driving electrodes are arranged in a matrix form, and the plurality of induction electrodes and the plurality of driving electrodes are alternately insulated and distributed.
Touch control display screen.

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